KR960015043B1 - Camera - Google Patents

Abstract

The apparatus and method automatically cuts off the electric power supplied for the circuits of the camera while closing a lens cap if a time has elapsed without using the camera. The apparatus comprises: a switch part(10) including a power control switch for initiating an operation of the camera, an encoder switch driven according to the state of the camera, and an operation switch operating the camera; a micro controller(20) generating a signal for cutting off the power and closing the lens cap; a power supply controller(30) cutting off the power according to the signal of the micro controller(20); a motor driver(40); a shutter driver(50); a distance sensor(60); a flash driver(70).

Description

Camera automatic power off device and its driving method

1 is a circuit diagram of an automatic power off device of a camera according to an embodiment of the present invention.

2 is a flowchart illustrating a method of driving an automatic power shut-off device of a camera according to an exemplary embodiment of the present invention.

The present invention relates to an automatic power shut-off device of the camera and a method of driving the same. More specifically, a lens cap is automatically applied when a user does not use the camera so that a predetermined time elapses after the user supplies power to the camera. The present invention relates to an automatic power shut-off device for a camera and a method of driving the same, which shuts off power and simultaneously cuts off power supplied to an accessory circuit.

In general, intermediate cameras and supply cameras have an auto focus control unit for automatically adjusting the focus of the lens, an auto exposure control unit for automatically controlling the exposure of the film, and film transfer for easy and easy operation of the camera. There is supplied an automatic camera equipped with an electronic circuit such as an auto-winding and rewinding drive unit for automatically controlling, and an auto flash drive unit for automatically replenishing insufficient light amount.

When the user wants to take a picture, such an automatic camera supplies power to accessory electronic circuits mounted in the automatic camera such as an auto focus control unit, an auto exposure control unit, an auto-winding and rewinding drive unit, and an auto flash drive unit. Must be supplied.

However, the conventional automatic camera has a disadvantage in that power consumption of the automatic camera is increased by continuously supplying power to an accessory circuit for controlling the operation of the automatic camera.

Such disadvantages cause inconveniences in that the user must separate a power supply such as a battery or a battery from the automatic camera in order to prevent power consumption by the automatic camera when the user does not use the automatic camera.

Therefore, the object of the present invention is to solve the above-mentioned disadvantages, and when the user does not use the camera for a certain time to elapse after supplying power to the camera, the lens cap is automatically closed and the accessory circuit The present invention provides an automatic power cut-off device for a camera and a method of driving the same, which can greatly reduce power consumption.

The configuration of the present invention for achieving the above object, the power control switch is turned on to start the operation of the automatic camera, the encoder switch that is turned on and off depending on the state of the camera and the operation switch for controlling the operation of the camera, etc. And the switch unit is included; A microcontroller for outputting a signal for shutting off power supplied to an accessory circuit while closing the lens cap when the camera is not used for a predetermined time after the operation of the camera is started; A power supply control unit which cuts off the power supplied to the accessory circuit when the power-off myth is input from the microcontroller; It consists of an accessory circuit such as a motor driver, a shutter driver, a distance measurer, and a flash driver connected to the microcontroller and the power supply controller.

Another configuration of the present invention for achieving the above object is that when the power supply voltage is applied, the operation is started to initialize all variables and accessory circuits, and the lens cap when the power control switch is turned on by reading whether the power control switch is turned on. Reads whether the lens cap is closed, and if the lens cap is not closed, reads whether the lens cap is closed by rotating the lens group driving motor in the reverse direction, and drives the lens group when the lens group driving motor is rotated in the reverse direction and the lens cap is closed. After stopping the motor operation, cut off the power supply to the accessory circuit.If the lens cap is closed after the power control switch is turned on, read the lens cap opening by rotating the lens group driving motor in the forward direction. When the motor rotates in the forward direction and the lens cap is opened, it controls the operation of the camera. If not, read out whether a certain time has elapsed, and if a certain time has elapsed, save the current state of the automatic camera, and if the lens cap is closed by reading whether the lens cap is closed by rotating the lens group driving motor backwards. The operation of the driving motor is stopped, the power supply to the accessory circuit is cut off after the operation of the lens group driving motor is stopped, and all the operations are completed.

With reference to the accompanying drawings, a preferred embodiment that can easily implement this invention by the above-described configuration will be described in detail.

1 is a circuit diagram of an automatic power off device of a camera according to an embodiment of the present invention.

As shown in FIG. 1, the automatic power shut-off device of the camera according to the embodiment of the present invention includes a switch unit 10 connected to an input terminal connected to ground GND, and an input terminal connected to an output terminal of the switch unit 10. And a microcontroller 20 having a power input terminal Vcc connected to a power voltage signal line B +, and a power supply having an input terminal connected to a power supply signal output terminal PS1 and a power voltage signal line B + of the microcontroller 20. Motor control unit 40, shutter drive unit 50, distance measuring unit 60, flash drive unit 70 connected to the control unit 30, the output terminal of the microcontroller 20 and the output terminal of the power supply control unit 30, respectively. )

The configuration of the switch unit 10 includes a power control switch SW11 and an encoder switch SW12-SW14, in which all switches used for detecting an operating state of the automatic camera or for operating the automatic camera ( Not shown).

The power supply control unit 30 includes a resistor R31 connected to one terminal of the power supply signal output terminal PS1 of the microcontroller 20 and a base connected to the other terminal of the resistor R31. And the emitter is grounded transistor Q31, resistor R32 connected between the collector and base of transistor Q31, resistor R33 connected at one terminal to the collector of transistor Q31, and resistor ( A PNP transistor Q32 having a base connected to the other terminal of R33 and an emitter connected to a power supply voltage signal line B +, and a resistor connected between the emitter and the base of the PNP transistor Q32; R34).

2 is a flowchart illustrating a method of driving an automatic power shut-off device of a camera according to an exemplary embodiment of the present invention.

As shown in FIG. 2, the method for driving the automatic power cut-off device of the camera according to the embodiment of the present invention includes the steps of starting operation 100 when a power voltage is applied, and initializing all variables and accessory circuits ( 110, a step of reading 120 whether the power control switch is on, a step of reading 130 whether the lens cap is closed when the power control switch is on, and a lens group when the lens cap is not closed Rotating 140 the drive motor in the reverse direction; reading 150 whether the lens cap is closed by rotating the lens group driving motor; and 150, when the lens cap is closed by rotating the lens group driving motor in the reverse direction. Interrupting the power supplied to the accessory circuit after stopping the operation of the lens group driving motor (160); and rotating the lens group driving motor in the forward direction when the lens cap is closed (170). And reading whether the lens cap is opened by rotating the lens group driving motor in the forward direction (180), and stopping the operation of the lens group driving motor when the lens cap is opened by rotating the lens group driving motor in the forward direction. 190, reading 200 whether the operation switch is on, step 210 when the camera is operated when the operation switch is on, and reading whether a certain time has elapsed when the operation switch is not on Step 220, storing a current state of the automatic camera when a predetermined time elapses, rotating the lens group driving motor in the reverse direction 240, and the lens group driving motor in the reverse direction. (250) reading whether the lens cap is closed by being rotated, stopping the operation of the lens group driving motor when the lens cap is closed by rotating the lens group driving motor in a reverse direction (260); After the operation of the lens group driving motor is stopped, a step 270 of cutting off power supplied to the accessory circuit and an end step 280 of terminating all operations are performed.

The operation of the automatic power cut-off device of the camera and its driving method according to the embodiment of the present invention by the above configuration is as follows.

When the power supply voltage B + is applied, the automatic power cutoff device of the camera according to the embodiment of the present invention operates.

When the auto power off device of the camera is operated, the microcontroller 20 initializes the accessory circuit by outputting a reset signal to the accessory circuit after initializing all variables stored in the internal memory.

Then, the high power supply signal PS1 is output from the microcontroller 20 to the power supply control unit 30, so that the power supply voltage B + is supplied to the motor driving unit through the PNP transistor Q32 of the power supply control unit 30. 40, the shutter driver 50, the distance measurer 60, and the flash driver 70.

Next, the microcontroller 20 checks whether the power control switch SW11 is turned on by reading whether the low state signal is input from the power control switch SW11 of the switch section 10.

The power control switch SW11 is a switch for turning on the automatic camera when the user wants to take a picture using the automatic camera.

When the power control switch SW11 is turned on, the microcontroller 20 outputs the high power supply signal PS1 to the power supply controller 30 so that the power voltage B + is the PNP type of the power supply controller 30. The transistor Q32 is applied to an accessory circuit such as the motor driver 40, the shutter driver 50, the distance measurer 60, and the flash driver 70.

At the same time, the microcontroller 20 reads the state of the encoder switches SW12 to SW14 of the switch unit 10 to read whether the lens cap is closed.

The encoder switches SW12 to SW14 are switches indicating the state of the camera as shown in Table 1 below.

(ON = switch is on, OFF = switch is off)

If the encoder switches SW12 to SW14 are in the fluorine state, the microcontroller 20 assumes that the lens cap is closed. If the encoder switches SW12 to SW14 are in the gap state, the microcontroller 20 opens the lens cap. It is assumed to be present.

When the lens cap is not closed according to the state of the encoder switches SW12 to SW14 after the power control switch SW11 of the switch unit 10 is turned on, the microcontroller 20 controls the lens by controlling the motor driver 40. Allow the group drive motor to rotate in the reverse direction.

When the lens group driving motor rotates in the reverse direction, the lens group barrel enters the inside of the automatic camera and the lens cap is closed in conjunction with this. Closing the lens cap prevents the lens from being soiled or damaged by foreign matter.

At this time, the microcontroller 20 reads the state of the encoder switches SW12 to SW14 to determine whether the lens cap is completely closed. When the lens cap is completely closed, that is, when the encoder switches SW12 to SW14 are in a closed state, the microcontroller 20 stops the operation of the lens group driving motor by controlling the motor driver 40.

Next, the microcontroller 20 outputs the low power supply signal PS1 to the power supply controller 30 so that the power voltage B + is supplied to the motor driver through the PNP transistor Q32 of the power supply controller 30. 40, the shutter driver 50, the distance measurer 60, and the flash driver 70 may be blocked from being applied to an accessory circuit.

When the power supply signal PS1 in the low state is applied from the microcontroller 20 to the base terminal of the transistor Q31 of the power supply control unit 30, the transistor Q31 is turned off. When the transistor Q31 is turned off, a high state signal is inputted to the base terminal of the PNP type transistor Q32, so that the PNP type transistor Q32 is turned off. Therefore, the power supply voltage B + applied to the motor driver 40, the shutter driver 50, the distance measurer 60 and the flash driver 70 is cut off.

However, when the lens cap is closed according to the state of the encoder switches SW12 to SW14 after the power control switch SW11 of the switch unit 10 is turned on, the microcontroller 20 controls the lens by controlling the motor driver 40. Allow the group drive motor to rotate in the forward direction.

When the lens group driving motor rotates in the forward direction, the lens group barrel opens to the outside of the automatic camera and the lens cap is opened in association with the lens group barrel.

At this time, the microcontroller 20 reads the state of the encoder switches SW12 to SW14 to determine whether the lens cap is completely open. When the lens cap is completely open, that is, when the encoder switches SW12 to SW14 are in a gap state, the microcontroller 20 stops the operation of the lens group driving motor by controlling the motor driving unit 40.

The microcontroller 20 then continues to see if there is a signal input from the switch section 10.

If there is an input of a signal of the operation switch from the switch unit 10, the microcontroller 20 executes the photographing operation of the automatic camera by driving the operation of the accessory circuit associated therewith.

However, if there is no signal input from the switch unit 10 so that a certain time elapses, the microcontroller 20 stores the current state of the automatic camera in the internal memory and controls the motor driving unit 40 to control the lens group driving motor. Rotate in the reverse direction.

When the lens group driving motor rotates in the reverse direction, the lens group barrel enters the inside of the automatic camera and the lens cap is closed in conjunction with this. Closing the lens cap prevents the lens from being soiled or damaged by foreign matter.

At this time, the microcontroller 20 reads the state of the encoder switches SW12 to SW14 to determine whether the lens cap is completely closed. When the lens cap is completely closed, the microcontroller 20 stops the operation of the lens group driving motor by controlling the motor driver 40.

Next, the microcontroller 20 outputs the low power supply signal PS1 to the power supply controller 30 so that the power voltage B + is supplied to the motor driver through the PNP transistor Q32 of the power supply controller 30. 40, the shutter driver 50, the distance measurer 60, and the flash driver 70 may be blocked from being applied to an accessory circuit.

Therefore, when the user does not use the automatic camera for a predetermined time after turning on the power control switch SW11 of the switch unit 10 to use the automatic camera, the micro controller 20 and the motor driving unit 40 are connected. In addition, the supply of the power supply voltage B + to the accessory circuits such as the shutter driver 50, the distance measurer 60, and the flash driver 70 may be cut off to prevent waste of power by the accessory circuit. There is a number.

As described above, in the embodiment of the present invention, when the user does not use the camera so that a certain time elapses after the power is supplied to the camera, the lens cap is automatically closed and at the same time, the power supplied to the accessory circuit is cut off. It is possible to provide an automatic power cut-off device for a camera and a driving method thereof having an effect of greatly reducing power consumption. This effect of the invention can be used in the field of automatic cameras.

Claims (3)

A switch unit 10 including a power control switch which is turned on to start the operation of the automatic camera, an encoder switch which is turned on and off according to the state of the camera, and an operation switch for controlling the operation of the camera; A microcontroller 20 for outputting a signal for shutting off the power supplied to the accessory circuit while closing the lens cap when the camera is not used for a predetermined time after the operation of the camera is started; A power supply control unit 30 which cuts off power supplied to an accessory circuit when a power cutoff signal is input from the microcontroller 20; After receiving power from the power supply controller 30, the motor driver 40 controlled by the microcontroller 20, the shutter driver 50, the distance measurer 60, the flash driver 70, and the like. Auto power off device for a camera, characterized in that it consists of an accessory circuit. The power supply controller 30 of claim 1, further comprising: a switching element Q31 turned on and off by a power supply signal PS1 of the microcontroller 20; A PNP transistor Q32 that turns on when the switching element Q31 is turned on to supply power to the accessory circuit, and turns off when the switching element Q31 is turned off to cut off the power supplied to the accessory circuit; An automatic power shut-off device for a camera, comprising a bias resistor (R34) connected between an emitter and a base of a PNP type transistor (Q32). When the power voltage is applied, the operation starts and initializes all variables and sub-circuits, and reads whether the power control switch is turned on, and reads whether the lens cap is closed when the power control switch is turned on and if the lens cap is not closed. Reads whether the lens cap is closed by rotating the lens group driving motor in the reverse direction, and stops the operation of the lens group driving motor when the lens group driving motor is rotated in the reverse direction and closes the lens cap. If the lens cap is closed after the power control switch is turned on, the lens group driving motor is rotated in the forward direction to read whether the lens cap is opened. If the lens group driving motor rotates in the forward direction, the lens cap opens After stopping the operation of the drive motor, it is read whether the operation switch is on and the operation switch is on In this case, it controls the operation of the camera, and if the operation switch is not turned on, it reads whether a certain time has elapsed and saves the current state of the automatic camera after a certain time has elapsed, and rotates the lens group driving motor in the reverse direction. Reading whether the lens cap is closed and stopping the operation of the lens group driving motor, cutting off the power supplied to the accessory circuit after the lens group driving motor is stopped, and terminating all the operations. A method of driving an automatic power cut-off device for a camera.